\name{plot.merMod}
\title{Diagnostic Plots for 'merMod' Fits}
\alias{plot.merMod}
\alias{qqmath.merMod}
\usage{
\method{plot}{merMod}(x,
     form = resid(., type = "pearson") ~ fitted(.), abline,
     id = NULL, idLabels = NULL, grid, \dots)
\method{qqmath}{merMod}(x, id = NULL, idLabels = NULL, \dots)
}
\arguments{
  \item{x}{a fitted [ng]lmer model}
  \item{form}{an optional formula specifying the desired
  type of plot. Any variable present in the original data
  frame used to obtain \code{x} can be referenced. In
  addition, \code{x} itself can be referenced in the
  formula using the symbol \code{"."}. Conditional
  expressions on the right of a \code{|} operator can be
  used to define separate panels in a lattice display.
  Default is \code{resid(., type = "pearson") ~ fitted(.)},
  corresponding to a plot of the standardized residuals
  versus fitted values.}

  \item{abline}{an optional numeric value, or numeric
  vector of length two. If given as a single value, a
  horizontal line will be added to the plot at that
  coordinate; else, if given as a vector, its values are
  used as the intercept and slope for a line added to the
  plot. If missing, no lines are added to the plot.}

  \item{id}{an optional numeric value, or one-sided
  formula. If given as a value, it is used as a
  significance level for a two-sided outlier test for the
  standardized, or normalized residuals. Observations with
  absolute standardized (normalized) residuals greater than
  the \eqn{1-value/2} quantile of the standard normal
  distribution are identified in the plot using
  \code{idLabels}. If given as a one-sided formula, its
  right hand side must evaluate to a logical, integer, or
  character vector which is used to identify observations
  in the plot. If missing, no observations are identified.}

  \item{idLabels}{an optional vector, or one-sided formula.
  If given as a vector, it is converted to character and
  used to label the observations identified according to
  \code{id}. If given as a vector, it is converted to
  character and used to label the observations identified
  according to \code{id}. If given as a one-sided formula,
  its right hand side must evaluate to a vector which is
  converted to character and used to label the identified
  observations. Default is the interaction of all the
  grouping variables in the data frame.  The special
  formula \code{idLabels=~.obs} will label the observations
  according to observation number.}

  \item{grid}{an optional logical value indicating whether
  a grid should be added to plot. Default depends on the
  type of lattice plot used: if \code{xyplot} defaults to
  \code{TRUE}, else defaults to \code{FALSE}.}

  \item{\dots}{optional arguments passed to the lattice
  plot function.}
}
\description{
  diagnostic plots for merMod fits
}
\details{
  Diagnostic plots for the linear mixed-effects fit are
  obtained. The \code{form} argument gives considerable
  flexibility in the type of plot specification. A
  conditioning expression (on the right side of a \code{|}
  operator) always implies that different panels are used
  for each level of the conditioning factor, according to a
  lattice display. If \code{form} is a one-sided formula,
  histograms of the variable on the right hand side of the
  formula, before a \code{|} operator, are displayed (the
  lattice function \code{histogram} is used). If
  \code{form} is two-sided and both its left and right hand
  side variables are numeric, scatter plots are displayed
  (the lattice function \code{xyplot} is used). Finally, if
  \code{form} is two-sided and its left had side variable
  is a factor, box-plots of the right hand side variable by
  the levels of the left hand side variable are displayed
  (the lattice function \code{bwplot} is used).

  \code{qqmath} produces a Q-Q plot of the residuals
  (see \code{\link{qqmath.ranef.mer}} for Q-Q plots of the
  conditional mode values).
}
\author{
  original version in \CRANpkg{nlme} package by Jose Pinheiro
  and Douglas Bates.
}
\examples{
data(Orthodont,package="nlme")
fm1 <- lmer(distance ~ age + (age|Subject), data=Orthodont)
## standardized residuals versus fitted values by gender
plot(fm1, resid(., scaled=TRUE) ~ fitted(.) | Sex, abline = 0)
## box-plots of residuals by Subject
plot(fm1, Subject ~ resid(., scaled=TRUE))
## observed versus fitted values by Subject
plot(fm1, distance ~ fitted(.) | Subject, abline = c(0,1))
## residuals by age, separated by Subject
plot(fm1, resid(., scaled=TRUE) ~ age | Sex, abline = 0)
library(lattice) ## needed for qqmath
qqmath(fm1, id=0.05)
ggp.there <- "package:ggplot2" \%in\% search()
if (ggp.there || require("ggplot2")) {
    ## we can create the same plots using ggplot2 and the fortify() function
    fm1F <- fortify.merMod(fm1)
    ggplot(fm1F, aes(.fitted,.resid)) + geom_point(colour="blue") +
           facet_grid(.~Sex) + geom_hline(yintercept=0)
    ## note: Subjects are ordered by mean distance
    ggplot(fm1F, aes(Subject,.resid)) + geom_boxplot() + coord_flip()
    ggplot(fm1F, aes(.fitted,distance)) + geom_point(colour="blue") +
        facet_wrap(~Subject) +geom_abline(intercept=0,slope=1)
    ggplot(fm1F, aes(age,.resid)) + geom_point(colour="blue") + facet_grid(.~Sex) +
        geom_hline(yintercept=0)+ geom_line(aes(group=Subject),alpha=0.4) +
        geom_smooth(method="loess")
    ## (warnings about loess are due to having only 4 unique x values)
    if(!ggp.there) detach("package:ggplot2")
}
}

